In the present invention, the recording paper is conveyed by a feed roller to plural recording portions sequentially, and each recording portion successively prints each specific color on the recording paper while applying tension to the paper. The tension applied to the recording paper is switched to a predetermined value each time the recording paper is conveyed to each recording, portion when starting to print.
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8. A color printer comprising:
a feed roller conveying a recording paper; plural recording portions located in the path of said paper downstream of said feed roller, and each printing a specific color ink on said paper; tension rollers located downstream of each recording portion, and which convey said recording paper from upstream to downstream by applying tension; and wherein the tension applied by the tension roller to said recording paper is switched to a predetermined value each time said recording paper is conveyed to each recording portion.
1. A method of paper feeding from a roll in a color printer for automatic printing sequentially at each of a plurality of recording portions in which a specific color is applied comprising the steps of:
conveying the paper end from a roll by feed rollers to the plural recording portions sequentially, printing at each recording portion a specific color on said recording paper beginning at the paper end; applying tension to the paper by tension roller while the printing takes place at each recording portion; and switching the tension being applied to a predetermined value at each said recording portion each time said recording paper is conveyed to each recording portion when starting to print.
9. A color printer comprising,
a feed roller conveying a recording paper; plural recording portions located in the path of said paper downstream of said feed roller, and each printing a specific color ink on said paper; tension rollers located downstream of each recording portion, and which convey said recording paper from upstream to downstream by applying tension; a frictional force-detecting portion detecting a frictional force between a thermal head located on said recording portion and said recording paper during printing; and a driving force control portion controlling a driving force of a motor to balance said frictional force detected by said frictional force-detecting portion and the diving force of the motor driving said tension rollers.
7. A method of paper feeding in a color printer in which recording paper is conveyed by feed rollers to plural recording portions sequentially, and each recording portion prints a specific color on said recording paper successively while applying tension, said method comprising the steps of:
applying tension to said recording paper by a tension roller, said tension being switched to a predetermined value each time said recording paper is conveyed to each recording portion when starting to print, wherein said recording portions further comprise: a frictional force-detecting portion detecting a frictional force between a thermal head located on said recording portion and said recording paper during printing; and a driving force control portion controlling a driving force of a motor to balance said frictional force detected by said frictional force-detecting portion and the driving force of the motor driving said tension rollers; and the tension applied to said recording paper is switched by said driving force control portion each time a front edge of said recording paper is conveyed in sequence to each recording portion when starting to print.
2. The method of
3. The method of
4. The method of
switching the tension applied to said recording paper is carried out when said recording paper is conveyed to said overcoat portion.
5. The method of
6. The method of
the tension acting on said recording paper is switched when said recording paper is provided with a gloss surface through heat treatment applied to said recording paper downstream of said recording portions.
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1. Field of the Invention
The present invention generally relates to a color printer for printing a full color image with plural thermal heads, and further relates to preventing the shear of the colors in printing, such as errors in dot positioning. Also, the present invention generally relates to paper feeding of color printers with plural thermal heads so as to prevent shear of the colors in printing.
Also, the invention generally relates to thermal heads, which are very useful for the above mentioned color printers, and which can be used in double-line thermal heads or preheat-type thermal heads. The present invention also generally relates to methods of making the thermal heads.
Furthermore, the invention generally relates to a lamp reflection board which reflects light from a lamp to thermal paper, and further relates to a small instrument such as the above mentioned color printer, in which it is very difficult to secure a sufficient optical path length.
2. Description of Related Art
Color Printer
There are many types of color printers, such as thermal transfer printers, ink-jet printers, and so on. Thermal transfer printers transfer ink from an ink ribbon onto recording paper by placing the ink ribbon against the recording paper, heating the thermal head and pressing it against the ink ribbon.
Recently, customers have required high speed printing from thermal transfer color printers. But the maximum printing speed is limited by four elements, i.e., as the characteristics of the ink ribbon dye, development of wrinkles, data transfer speed, and the response speed of the thermal head.
The recording paper 3 is conveyed from paper roll 2 by feed roller 4 and pinch roller 5. The feed roller 4 has a small protuberance on its surface, and is driven by a pulse motor (not shown in FIG. 1). Downstream of the fourth print portion id, there is a paper discharging roller 6 for discharging the recording paper 3, and cutter 8 for cutting the recording paper 3 to a pre-determined length.
Each print portion 1a, 1b, 1c has thermal heads 9a, 9b, 9c, platen rollers 10a, 10b, 10c, ink ribbon supply rollers 12a, 12b, 12c, ink ribbon take-up rollers 13a, 13b, 13c, tension rollers 14a, 14b, 14c, and pinch rollers 15a, 15b, 15c. The platen rollers 10a, 10b, 10c are located opposite the print portions 1a, 1b, 1c, respectively. The ink ribbon supply rollers 12a, 12b, 12c supply each color of ink ribbon 11a, 11b, 11c to the respective thermal heads 9a, 9b, 9c. The ink ribbon take-up rollers 13a, 13b, 13c respectively take up each color of ink ribbon 11a, 11b, 11c. The tension rollers 14a, 14b, 14c are located downstream of the respective thermal heads 9a, 9b, 9c. The pinch rollers 15a, 15b, 15c are located opposite the tension rollers 14a, 14b, 14c, respectively.
Similar to each print portion 1a, 1b, 1c, the overcoat portion 1d has thermal head 9d, platen roller 10d, overcoat ribbon 11d, overcoat ribbon supply roller 12d, overcoat ribbon take-up roller 13d, tension roller 14d, and pinch roller 15d. The overcoat ribbon supply roller 12d supplies overcoat ribbon 11d to the thermal head 9d. The overcoat ribbon take-up roller 13d takes up the overcoat ribbon 11d. The tension roller 14d is located downstream of the thermal head 9d. The pinch roller 15d is located opposite the tension roller 14d.
F1, F2, F3, and F4 indicate the thrust tension of each of tension rollers 14a, 14b, 14c, and 14d. W1, W2, W3, and W4 indicate the frictional forces of each thermal transfer mechanism. T0 indicates the tension of the feed roller 4, and T1, T2, T3, and T4 indicate the tension of the paper 3 between the tension rollers 14a, 14b, 14c, 14d and the thermal heads 9a, 9b, 9c, 9d at the print portions 1a, 1b, 1c and overcoat portion 1d.
At the above mentioned color printer 1, the front edge of paper 3 pulled out from paper roll 2 is conveyed between feed roller 4 and pinch roller 5 by a paper feeding mechanism (not shown in FIG. 1). Then the front edge of paper 3 is caught between feed roller 4 and pinch roller 5, passes between the thermal head 9a and platen roller 10a, and is conveyed to a location between tension roller 14a and pinch roller 15a.
At this point, the thermal head 9a is pressed against platen roller 10a sandwiching the paper 3, and pinch roller 16a is pressed against tension roller 14a sandwiching the paper 3. Then, tension roller 14a is driven by a DC motor (not shown in
After the yellow image printing is over, the front edge of paper 3 reaches a location between tension roller 14a and pinch roller 15a. At this point, the thermal head 9b is pressed into platen roller 10b sandwiching the paper 3, and pinch roller 15b is pressed into tension roller 14b sandwiching the paper 3. Then, tension roller 14b is driven by a DC motor (not shown in
After the magenta image printing is over, the front edge of paper 3 reaches the location between tension roller 14c and pinch roller 15c. At this point, tension roller 14c is driven by a DC motor (not shown in
When the front edge of paper 3 reaches the location between tension roller 14d and pinch roller 15d, the thermal head 9d is pressed against platen roller 10d sandwiching the paper 3, and pinch roller 15d is pressed against tension roller 14d, sandwiching the paper 3. Then, tension roller 14d is driven by a DC motor (not shown in
When overcoat is printed on a first portion of the paper 3 at the thermal head 9d, the second cyan image is printed on a second portion of the paper 3 at the thermal head 9c, the third magenta image is printed on a third portion of the paper 3 at the thermal head 9b, and the fourth yellow image is printed on a fourth portion of the paper 3 at the thermal head 9a. After overcoat printing is over, the front edge of paper 3 reaches cutter 8, passing through paper discharging roller 6 and pinch roller 7. The cutter 8 cuts the first portion of the paper 3 and a paper storage area (not shown in
The above mentioned color printer and paper feeding have the following requirements. The first requirement is stability of the tension of the paper 3 during printing. Generally, the thrust tension F1, F2, F3, and F4 of each tension roller 14a, 14b, 14c, and 14d are made constant. Therefore, the tension affecting paper 3 and working on feed roller 4 changes incrementally from the first paper printing portion to the third paper printing portion.
The second requirement is stability of the conveyance ratio. As shown in
To summarize above arguments of the color printer, the changes of the tension acting on the paper cause tension and extension of the paper; as well as a change of the tension acting on the feed roller 4 during continuous printing of a first portion of the paper to a third portion of the paper. Changes in tension acting on the paper result in changes of the conveyance length of the paper, which lead to shear of the colors in printing during the placing of color dots. Next to a third portion of the paper, the shear of the colors in printing is relatively small, because changes in tension occur within a limited range. To avoid shear of the colors for the first three portions of the paper, one conventional solution is to discard the first three portions of the paper without color printing. However, this method causes much waste of paper 3.
The third requirement is to avoid lateral print shading. In the case of a color printer using the thermal transfer method or thermal color development method, the frictional coefficient between the exothermic portion of the thermal head and the paper or ink ribbon fluctuates depending on the energy acting on the exothermic portion and the quantity of heat stored in the thermal head. This fluctuation occurs in each line of printing, and occurs on a millisecond order period in the time domain. This fluctuation of tension on the millisecond order leads to lateral print shading on recording paper 3, which reduces the printing quality. Furthermore, as shown in
Thermal Head
Japanese Unexamined Patent Publication, First Publication No. Sho 62-217627 discloses the invention of double line thermal heads, which have plural exothermic resistance portions with two lines in parallel to speed up printing. Double line thermal heads can cut the time for printing in half, in principle, because these thermal heads print two lines at the same time. Japanese Unexamined Patent Publication, First Publication No. Hei 08-300695 discloses an invention of a preheat-type thermal head with a metal plate, which speeds up printing.
However there are some problems with double line thermal heads. The first problem is peeling off at the boundary between the common electrode and alumina base when heating, because the thermal expansion coefficients of the bulk metal of the common electrode and of the alumina base are not the same. The second problem is that peeling off at the boundary of the electrode and alumina base causes thermal stress to the thin-film electrode, which builds up on the common electrode, and the thermal stress can damage the thin film, which has portions with low mechanical strength. Furthermore, peeling off at the boundary of the electrode and alumina base makes it difficult to smoothly connect the common electrode and the alumina base, and the thermal stress breaks the thin film formed on the common electrode.
The third problem is the difficulty in manufacturing a common electrode, which should have positioning accuracy within fine width of the dot level of the thermal head. It is very difficult to connect the common electrode with the alumina base without gaps or openings, and it is very difficult to cover the alumina base with the common electrode without gaps or openings. Even if these problems were overcome, a fourth problem occurs in that is difficult to print with high density with double line thermal heads, because there is the opening between the double lines in exothermic resistance portion, and the width of the opening is coincident to the width of the common electrode.
There are some problems with preheat type thermal heads. The first problem is that it is difficult to complete a predetermined shape precisely for all lengths of substrate in the process of producing a common electrode on a stainless substrate with etching or mechanical processing, with increases the cost. The second problem is that air bubbles remain in the glass glaze. In the process of screen-printing and baking of the glass paste, it is difficult to bake a stainless substrate with a baking temperature as high as that of the ceramic substrate. As the result of the relatively low baking temperature, the viscosity of the glass glaze remains high, and high viscosity hinders elimination of air bubbles in the glass glaze. The third problem is damage to the thin film formed on the common electrode, because air bubbles appear on the surface of common electrode through lapping or polishing of the preheat type thermal head. The fourth problem is that it is difficult to complete the preheat type thermal head with precise lapping or polishing over the entire length of the substrate. The lapping or polishing of the thermal heads is carried out to make the common electrode appear on the surface of the thermal heads.
Even if these problems were solved, a fifth problem would remain, which is a large loss of heat at the common electrode while the paper passes through the first line exothermic resistance portion to reach the second line exothermic resistance portion. The reason for the fifth problem is that the common electrode is located between the double lines of the exothermic resistance portion in the case of a preheat type thermal head.
Lamp Reflex Board
Lamp reflex boards are attached thermal recording devices such as color printers.
The height H* of reflex board 40 from the surface of paper 3 is expressed by following equation.
It is desirable for the thermal recording device to be small, to make it easy to secure a place for the thermal recording device. Therefor it is desirable to make the width W* of the reflex board 40 narrow. According to the structure of the thermal recording device in
It is the first object of the present invention to provide a color printer and a method of paper feeding which can prevent shear of the dots of each color arising from stretching of the paper by maintaining the tension acting on the paper constant to within a tolerance level. And it is also the first object of the present invention to provide a color printer and a method of paper feeding which can prevent shear of the dots of each color arising from irregular feeding by maintaining the paper feeding distance constant, which maintains the tension acting on the feed roller constant to within a tolerance level.
It is the second object of the present invention to provide a thermal transfer method or thermal color development method for a color printer which is provides high quality printed image by preventing lateral print shading of the printed image.
It is the third object of the present invention to provide a thermal head and a method of making the same, which is made by a simpler manufacturing process compared with conventional process to manufacture double-line thermal heads and preheat thermal heads.
It is the fourth object of the present invention to provide a thermal head which can print with higher density compared with conventional double-line thermal heads.
It is the fifth object of the present invention to provide a thermal head which has higher heat efficiency compared with conventional preheat thermal heads.
It is the sixth object of the present invention to provide a lamp reflex board, which has small width and which can make the light radiated by the back of the lamp reach the surface of the paper with two or one reflections.
The present invention of a method of paper feeding in a color printer provides an advantageous feature of achieving the first object. In the present invention, the recording paper is conveyed by a feed roller to plural recording portions sequentially, and each recording portion successively prints each specific color on the recording paper while applying tension to the paper. The tension applied to the recording paper is switched to a predetermined value each time the recording paper is conveyed to each recording portion when starting to print.
Therefore the present invention of a method of paper feeding in a color printer can provide a tension applied to the recording paper which is switched to a predetermined value each time the front edge of the recording paper is conveyed to each recording portion when starting to print. For example, when the front edge of the recording paper reaches the first recording portion, a tension is applied to the recording paper in excess of the frictional force experienced by the recording paper at the first recording portion. This provides a tension corresponding to the frictional force experienced by the recording paper at the first recording portion, and a further tension in excess of the frictional force of the feed roller.
When the front edge of the recording paper reaches the second recording portion, the tension at the second recording portion is set to be in excess of the frictional force of the recording paper in the same manner as described above for the first recording portion. At the same time, the tension at the first recording portion is set to correspond to the frictional force on the recording paper. This makes the tension correspond to the frictional force on the recording paper at the first and second recording portions, and provides a tension in excess of the frictional force of the feed roller between the second recording portion and the first recording portion.
The present invention of a color printer provides an advantageous feature of achieving the first object. In the present invention, the color printer comprises a feed roller, plural recording portions, and tension rollers. The feed roller conveys the recording paper. The plural recording portions are located along the paper path downstream of the feed roller, and each prints a specific color ink on the paper. The tension rollers are located downstream of each recording portion, and convey the recording paper from upstream to downstream by applying tension. Furthermore, the tension that the tension rollers apply to the recording paper is switched to a predetermined value each time the recording paper is conveyed to each recording portion.
Therefore the present invention of a color printer can provide a tension applied to the recording paper which is switched to a predetermined value each time the front edge of the recording paper is conveyed to each recording portion when starting to print. For example, when the front edge of the recording paper reaches the recording portion, tension is applied to the recording paper in excess of the frictional force of the recording paper at the recording portion. This makes the tension correspond to the frictional force on the recording paper at the recording portion, and provides a further tension in excess of the frictional force of the feed roller.
The present invention of a color printer also provides the advantageous feature of achieving the second object. In the present invention, the color printer comprises a feed roller, plural recording portions, tension rollers, a frictional force detecting portion, and a driving force control portion. The feed roller conveys the recording paper. The plural recording portions are located along the paper path downstream of the feed roller, and each prints a specific color ink on the paper. The tension rollers are located downstream of each recording portion, and convey the recording paper from upstream to downstream by applying tension. The frictional force-detecting portion detects a frictional force between the thermal head located on the recording portion and the paper during printing. The driving force control portion controls the driving force of the motor to balance the frictional force detected by the frictional force detecting portion and the driving force of the motor driving the tension roller.
The present invention of a thermal head provides the advantageous feature of achieving the third, fourth, and fifth objects. In the present invention, the thermal head comprises a first layer of an electric circuit pattern, an insulator layer, and a second layer of an electric circuit pattern. The first layer of the electric circuit pattern has an electric circuit pattern formed on a ceramic substrate. The insulator layer is formed on the layer of the electric circuit pattern. The second layer of the electric circuit pattern has an electric circuit pattern formed on the insulator layer.
The present invention of a lamp reflex board provides an advantageous feature of achieving the sixth object. In the present invention, the lamp reflex board reflects radiant light from the back and side of the lamp onto an irradiation surface, and comprises a rear reflex board, a rear-side reflex board, and a side reflex board. The rear reflex board is located at the back of the lamp, and it reflects radiant light from the back of the lamp to the side of the lamp. The rear-side reflex board is located to the back and side of the lamp, and it reflects catoptric lights from the rear reflex board onto the irradiation surface. The side reflex board is located to the side of the lamp, and it reflects radiant light from the side of the lamp onto the irradiation surface.
The rear reflex board and rear-side reflex board reflect radiant light from the back of the lamp onto the irradiation surface and the side reflex board reflects radiant light from the side of the lamp to the irradiation surface. Compared with a conventional reflector of a concave mirror, the rear reflex board, rear-side reflex board, and side reflex board are provided as separate pieces. This makes the width of lamp reflex board narrow.
These and other objects and advantages of this invention will become more apparent and more readily appreciated from the following detailed description of the presently preferred exemplary embodiment of the invention, taken in conjunction with the accompanying drawings, of which:
Embodiment 1: Color Printer
From
The feed roller 19 is arranged opposite pinch roller 20, on the other side of paper 3, and the paper discharging roller 6 is arranged opposite of a pinch roller 7 on the other side of paper 3. The feed roller 19 has small protuberances on its surface, and it is driven so as to revolve by a pulse motor 21. Each print portion 1a, 1b, 1c respectively comprises thermal heads 9a, 9b, 9c; platen rollers 10a, 10b, 10c arranged opposite of the thermal heads 9a, 9b, 9c; ink ribbon supply rollers 12a, 12b, 12c supplying each color of ink ribbon 11a, 11b, 11c to the thermal heads 9a, 9b, 9c; ink ribbon take-up rollers 13a, 13b, 13c taking up the ink ribbon 11a, 11b, 11c. The ink ribbon 11a is yellow, the ink ribbon 11b is magenta, and the ink ribbon 11c is cyan ink ribbon.
There is a tension roller 23a to apply tension to the paper 3 conveyed from the print portion 1a, and pinch roller 24a is arranged opposite of the tension roller 23a downstream of print portion 1a. Similarly to the print portion 1a, there are tension rollers 23b, 23c to apply tension to the paper 3 conveyed from the print portions 1b, 1c; and pinch rollers 24b, 24c are arranged opposite of the tension rollers 23b, 23c downstream of the print portions 1b, 1c. These tension rollers 23a, 23b, 23c are driven with predetermined tension by voltage control of a DC motor (not shown in FIG. 7), and the tension of the each of tension rollers 23a, 23b, 23c is switched at the desired timing.
Further, as similarly to the print portions 1a, 1b, 1c; there are the thermal head 9d, platen roller 10d, overcoat ribbon 11d, overcoat ribbon supply roller 12d to supply the overcoat ribbon 11d to the thermal head 9d, and overcoat ribbon take-up roller 13d to take up the overcoat ribbon 11d at the overcoat portion 1d. And downstream of the overcoat portion 1d, there are the tension roller 23d to apply tension to the paper 3 conveyed from the overcoat portion 1d, and pinch roller 24d is arranged opposite of the tension roller 23d. This tension roller 23d is driven with a predetermined tension by voltage control of a DC motor (not shown in FIG. 7), and the tension is switched at desired timing.
The following description is the color printing process for the paper 3 with the above mentioned color printer. In
The following are the equations for the frictional force at each print portion 1a, 1b, 1c and the overcoat portion 1d, because the structure is common to each print portion 1a, 1b, 1c and the overcoat portion 1d;
And these frictional forces W1, W2, W3, W4 have an action-reaction relationship with tensions T1, T2, T3, T4 at each print portions 1a, 1b, 1c and the overcoat portion 1d. And these frictional forces W, W2, W3, W4 have same value as tension T1, T2, T3, T4 at each print portion 1a, 1b, 1c and the overcoat portion 1d.
First, the front edge of the paper 3 is pulled from the paper roll 2 and conveyed between the feed roller 19 and the pinch roller 20 through the paper guide rollers 17, 18 by a paper feeding mechanism (not shown in FIG. 7 and FIG. 8). At this point, the paper 3 is sandwiched between the feed roller 19 and the pinch roller 20. Then the paper 3 is further conveyed between the tension roller 23a and the pinch roller 24a through a gap between the thermal head 9a and the platen roller 10a of the print portion 1a by the feed roller 19, which is driven by pulse motor 21 to rotate in accordance with a predetermined conveyance length of the paper 3.
At this point, the thermal head 9a is pressed against the platen roller 10a via the paper 3, and the pinch roller 24a is pressed against the tension roller 23a via the paper 3. Then, the tension roller 23a is driven by the DC motor with thrust tension F1 to apply a constant tension to the paper 3. Yellow ink ribbon 11a is conveyed downstream with the paper 3, in synchronization with the printing speed, and it prints a yellow image on the paper 3 through the thermal head 9a. The conveyed yellow ink ribbon 11a is taken up by the ink ribbon take-up roller 13a.
At the same time, the tension roller 23a is driven by larger force than a frictional force at the print portion 1a, and by a longer conveyance length than the predetermined conveyance length of the paper 3 at the feed roller 19. But the feed roller 19 acts as a brake to regulate the conveyance length, and makes the conveyance length of the paper 3 constant downstream of the feed roller 19. Therefore, the paper 3 between the tension roller 23a and the thermal head 9a is subject to a tension T1, which has the same value as the frictional force W1 at the print portion 1a. And the feed roller 19 is subject to a tension due to the difference between thrust tension F1 and tension T1. In the other words, as shown in
After printing of the yellow image is completed, the front edge of the paper 3 is conveyed between the tension roller 23b and the pinch roller 23b through the gap between the thermal head 9b and the platen roller 10b of the print portion 1b. At this point, the thermal head 9b is pressed against the platen roller 10b through the paper 3, and the pinch roller 24b is pressed against the tension roller 23b through the paper 3. Then, the tension roller 23b is driven by the DC motor with thrust tension F2 to apply constant tension to the paper 3. Magenta ink ribbon 11b is conveyed downstream with the paper 3 in synchronization with the printing speed, and prints a magenta image on the paper 3 with the thermal head 9b. The conveyed magenta ink ribbon 11b is taken up by the ink ribbon take-up roller 13b.
At the same time of the magenta image printing for a first portion of the paper by the thermal head 9b, a yellow image is printed on a second portion of the paper by the thermal head 9a. In the same manner as for the yellow image, the tension roller 23b is driven by a larger force than the frictional force at the print portion 1b, and so as to provide a longer conveyance length than the predetermined conveyance length of the paper 3 at the feed roller 19. This means that the thrust tension F2 of the tension roller 23b is switched from zero to T+αT, and the thrust tension F1 of the tension roller 23a is switched from T+αT to T, and the tension roller 23a is driven.
At this time, there is a balance between the thrust tension F1 and the frictional force W1 at the print portion 1a. As a result, the a first portion of the paper 3 between the tension roller 23b and the thermal head 9b is subject to a tension T2, which has the same value as the frictional force W2 at the print portion 1b. The feed roller 19 receives the tension due to the difference between thrust tension F2 and tension T2 through the print portion 1a. As shown in
After printing of the magenta image is completed, the front edge of the paper 3 is conveyed between the tension roller 23c and the pinch roller 23c through the gap between the thermal head 9c and the platen roller 10c of the print portion 1c. At this point, the thermal head 9c is pressed against the platen roller 10c sandwiching the paper 3, and the pinch roller 24c is pressed against the tension roller 23c sandwiching the paper 3. Then, the tension roller 23c is driven by the DC motor with thrust tension F3 to apply constant tension to the paper 3. And cyan ink ribbon 11c is conveyed downstream with the paper 3 in synchronization with the printing speed, and it prints a cyan image on the paper 3 through the thermal head 9c. The conveyed cyan ink ribbon 11c is taken up by the ink ribbon take-up roller 13c.
At the same time of the cyan image printing for the a first portion of the paper by the thermal head 9c, a magenta image is printed on a second portion of the paper by the thermal head 9b, and a yellow image is printed on a third portion of the paper by the thermal head 9a. In the same manner as for the magenta image, the tension roller 23c is driven by larger force than the frictional force at the print portion 1c, and so as to provide a longer conveyance length than the predetermined conveyance length of the paper 3 at the feed roller 19. This means that the thrust tension F3 of the tension roller 23c is switched from zero to T+αT, and the thrust tension F2 of the tension roller 23b is switched from T+αT to T, the thrust tension F1 of the tension roller 23a is maintained at T, and the tension rollers 23a, 23b are driven.
As the same process is working at time 3 as that for times 1 and 2, at the time 3 for printing cyan on a first portion of the paper, the thrust tension F1 of the tension roller 23a is maintained at T, the thrust tension F2 of the tension roller 23b is switched from T+αT to T, and the thrust tension F3 of the tension roller 23c is switched from zero to T+αT. Then, respective tensions T1, T2, T3 acting on a second portion of the paper 3 between the tension rollers 23a, 23b, 23c and the thermal heads 9a, 9b, 9c are set to T. and the tension T0 acting on the feed roller 19 is set to αT. Furthermore, the thrust tension F4 is set to zero, because the tension roller 23d is not active.
After the printing of the cyan image is completed, the front edge of the paper 3 is conveyed between the tension roller 23d and the pinch roller 23d through the gap between the thermal head 9d and the platen roller 10d of the print portion 1d. At this point, the thermal head 9d is pressed against the platen roller 10d sandwiching the paper 3, and the pinch roller 24d is pressed against the tension roller 23d sandwiching the paper 3. Then, the tension roller 23d is driven by the DC motor with a thrust tension F4 to apply a constant tension to the paper 3, and overcoat ribbon lid is conveyed downstream with the paper 3 in synchronization with the printing speed, and it overcoat-prints with the thermal head 9d on the paper 3 having printed thereon overlapping yellow, magenta, and cyan images. The conveyed overcoat ribbon lid is taken up by overcoat ribbon take-up roller 13d.
At the same time overcoat printing is carried out for the first portion of the paper by the thermal head 9d, a cyan image is printed on a second portion of the paper by the thermal head 9c, a magenta image is printed on a third portion of the paper by the thermal head 9b, and a yellow image is printed on a fourth portion of the paper by the thermal head 9a. In the same manner as for the cyan image, the tension roller 23d is driven by a larger force than the frictional force at the overcoat portion 1d, and so as to provide a longer conveyance length than the predetermined conveyance length of the paper 3 at the feed roller 19. This means that the thrust tension F4 of the tension roller 23d is switched from zero to T+αT, and the thrust tension F3 of the tension roller 23c is switched from T+αT to T. the thrust tensions F1 and F2 of the tension rollers 23a, 23b are maintained at T, and the tension rollers 23a, 23b, 23c are driven.
As the same process is working at time 4 as that at times 1,2 and 3, at the time 4 for overcoat printing of a first portion of the paper, the respective thrust tensions F1 and F2 of the tension rollers 23a, 23b are maintained at T, thrust tension F3 of the tension roller 23c is switched from T+αT to T, and thrust tension F4 of the tension roller 23d is switched from zero to T+αT. Then, the respective tensions T1, T2, T3, T4 acting a second portion of the paper 3 between the tension rollers 23a, 23b, 23c, 23d and the thermal heads 9a, 9b, 9c, 9d are set to T, and tension T0 acting on the feed roller 19 is set αT. reaches After the overcoat printing is over, the front edge of a first portion of the paper 3 reaches the cutter 8 through the gap of the paper discharging roller 6 and the pinch roller 7. Finally, the cutter 8 cuts a first portion of the paper, which has been printed with yellow, magenta, and cyan images and overcoat printed, and holder 22 holds the first portion of the paper. After the above mentioned process is over, the printing of the paper is finished.
According to embodiment 1 for a color printer and a method of paper feeding, the tension acting on the paper 3 at the each of print portions 1a, 1b, 1c, and the overcoat portion 1d is switched each time the front edge of the paper 3 is conveyed to each print portion 1a, 1b, 1c, and the overcoat portion 1d. So, tensions T1, T2, T3, T4 acting on the paper 3 located between the tension rollers 23a, 23b, 23c, 23d and the thermal heads 9a, 9b, 9c, 9d remain constant within limited rage of acceptance; and also, tension T0 acting on the feed roller 19 remains at a constant value αT, wherever the paper 3 is located.
The prevention expansion and contraction of paper 3 prevents shear of the colors during printing of each color's dots at each print portion 1a, 1b, 1c. The prevention changes of tension acting on the feed roller 19 prevents shear of the colors by uneven conveyance lengths of the paper 3. As the result, it is possible to maintain a predetermined accuracy of printing of each color's dots even in the beginning of printing, and it is not necessary to throw away the first three papers 3, which reduces waste.
According to embodiment 1 for a color printer and method of paper feeding, the overcoat portion 1d is added to the print portions 1a, 1b, 1c to overcoat the paper 3 after each color image is printed. The prevention of shear of the colors in printing and overcoating can be achieved by maintaining a constant tension acting on the paper 3 at the overcoat portion 1d and tension acting on the paper 3 at the print portions 1a, 1b, 1c, when the front edge of paper is conveyed to the overcoat portion 1d.
The embodiment 1 shows the construction of a color printer having an overcoat portion 1d downstream of the print portions 1a, 1b, 1c, color printers having the print portions 1a, 1b, 1c without the overcoat portion 1d are also known to those skilled in the art. And also, the embodiment 1 shows the construction of a color printer having printed yellow, magenta, and cyan image overlapping on the paper 3, color printers having two color images overlapping on the paper 3, or four or more over color images overlapping on the paper 3 are also known to those skilled in the art.
The embodiment 1 also shows the construction of a color printer applying tension to the paper 3 by the tension rollers 23a, 23b, 23c, 23d, color printers having tension applied to portions at the print portions 1a, 1b, 1c and the overcoat portion 1d respectively to apply tension to the paper 3 are also known.
It is noted that the embodiment 1 shows a color printer using ink ribbons but color printers using thermal color development methods without ink ribbons may bring the same advantages as those of the color printer using ink ribbons. It is also noted that the embodiment 1 shows a color printer which switches the tension acting on the paper by the tension rollers, when the recording paper is conveyed to print portions 1a, 1b, 1c and the overcoat portion 1d. This makes tension acting on the paper conveyed to the print portion be maintained within a limited range, wherever the front edge of the paper located. And also, it maintains constant the tension acting on the feed roller. This prevents the shear of the colors in printing caused by expansion and contraction of the paper and changes of the conveyance length of the paper.
Embodiment 2
In the case of a color printer using the thermal transfer method or the thermal color development method, the frictional coefficient between an exothermic portion of a thermal head and a paper or ink ribbon fluctuates depending on the energy acting on the exothermic portion and the quantity of heat stored in the thermal head. These fluctuation occurs with the each line of printing, and on a millisecond order timescale. Tension control according to embodiment 1 may be able to prevent the lateral print shading on recording the paper 3. However, customers require more precise paper feeding, and it is difficult to control tension fluctuations on a millisecond order by tension control applying the above-mentioned embodiment 1, and tension fluctuations on the millisecond order cause lateral print shading on the recording paper 3, which decreases the quality of printing.
The object of the second embodiment of a color printer is to provide a paper feeding mechanism which can prevent tension fluctuations on the millisecond order by balancing the tension fluctuations sensed by a load cell and the tension produced by a DC motor to chive the tension rollers 23a, 23b, 23c. The tension fluctuations between the exothermic portion of the thermal head and the paper or the ink ribbon occurs at each line of printing. Furthermore, the second embodiment of a color printer may provide fine quality of printing without lateral print shading.
The following are the factors determining the frictional forces at the thermal heads.
(i) The pressing force at the thermal heads.
(ii) The supplied energy per a line to print
(iii) The temperature of the thermal heads of thermal printing.
(iv) The estimated energy stored in the thermal heads and the paper contacting portion.
The second embodiment provides a color printer using the thermal transfer method or thermal color development method with fine quality of printing without lateral print shading, by controlling the tension. The first control of tension is carried out to make the tension correspond to the frictional force on the paper at recording portion by applying a tension to the paper excess of the frictional force of the paper at the print portion, when the front edge of the first portion of the paper reaches the first print portion. The second control of tension is carried out the feed roller to balance the frictional force by motor driving force control portion.
Embodiment 3--Thermal Head
FIG. 12 and
In
After the ceramic substrate is formed, a first layer of an electric circuit pattern is formed upon the ceramic substrate by the following process. First, a resistance film 103 is formed by sputtering of TaSiO2, for example; and patterned by photolithography and etching. The resistance film 103 has a dot pattern, and similar to the exothermic portion 109 shown in
In the next process, electrode films 105, 106 are formed by sputtering of aluminum alloy, and patterned by photolithography and etching. The pattern of the electrode film 105, 106 is not only divided into dot as for the electrode film 111 as shown in
The third process is forming the insulator layer 107 by sputtering of SiO2 to 8 μm thickness within the range between line B and line B', for example. The right edge of the electrode film 106 is located to the left side of the line B', and there is electrical insulation between the first layer from the second layer. The electrode film 105 and the electrode film 106 are connected with flexible electrodes or terminals at the extended portion (not shown in FIG. 13). The insulator layer 107 electrically insulates the first layer from the second layer of the electric circuit pattern. Other materials for the insulator layer 107 are also known to be available to those skilled in the art, such as Ta2O5, SiC, SiAlON, SiN, DLC (Diamond Like Carbon), BN, BO2, TiO2, TiN, and their chemical compounds and mixtures of them. The method of forming the insulator layer 107 and the method of patterning the insulator layer 107 are similar to that of the resistance film 103.
The insulator layer 107 conducts heat generated at the exothermic portion 104 to surface of the thermal head, so the materials of the insulator layer 107 have high thermal conductivity and the thickness of the insulator layer 107 is made as small as possible while providing insulation. The insulator layer 107 can be formed of plural layers with two or more materials. The insulator layer 107 has bump at its surface corresponding to the thickness of the electrode films 105, 106. Therefore, surface of the insulator layer 107 should be polished to eliminate this bump.
The fourth process is the formation of a second layer of the electric circuit pattern upon the insulator layer 107 by the following procedure. First, resistance film 108 is formed by sputtering of TaSiO2, for example, and patterned by photolithography and etching. The pattern of the resistance film 108 is a divided dot pattern as shown in FIG. 13. The left edge of the resistance film 108 is located to the right side of the line B, and there is electrical insulation between the first layer and the second layer. However, those skilled in the art know that the materials, and methods of forming and patterning the resistance film are not limited those mentioned above, and that a procedure similar to that of the resistance film 103 at the first layer can also be used.
In the next procedure, electrode film 110, 111 is formed by sputtering of aluminum alloy, and patterned by photolithography and etching. The pattern of the electrode film 110, 111 is divided into dots to coincide with the resistance film 108. The exothermic portion 109 is an exposed part located between the electrode film 110 and the electrode film 111 of the resistance body. The exothermic portion 109 is shifted in the sub scan direction as shown in
It is preferable that the second layer of the electrode film have the characteristic of high thermal conductivity and strong heat-resistance, because the heat generated at the first layer of the electrode film is transmitted to the surface of the thermal head though the second layer of the electrode film 110. The left side of the extension part of the electrode film 110 is connected to the resistance film 108, and the electrode film 110 forms common electrode film 113. The left edge of common electrode film 113 is located to the right side of line B, and there is electrical insulation between the first layer and the second layer. The common electrode film 113 is connected with flexible electrodes or terminals at the extended portion (not shown in FIG. 13). The electrode film 111 is connected with control IC (not shown in
In the final procedure, protection film 112 is formed by sputtering of SiAlON to a 5 μm thickness, for example. But those skilled in art know that the materials, method of forming, and thickness of the protection film 112 are not limited to those mentioned above, but can also be similar to those of the insulator layer. There is also possible to use plural layers with plural materials to form the protection film 112. It is preferable to eliminate bump by polishing the surface of the protection film 112.
The following description is the control method of the thermal head in the third embodiment. The control IC (not shown in
Embodiment 4--Thermal Head
FIG. 12 and
The following describes the control method of the thermal head of the fourth embodiment. Control IC (not shown in
When printing with the first layer, the heat generated at the exothermic portion 104 is transmitted to the surface of the thermal head through the insulator layer 107, the second layer of the resistance film 108, the electrode film 110 and the protection film 112. On the other hand, when printing with the second layer, the heat generated at the exothermic portion 109 is transmitted to the surface of the thermal head through the protective film 112. Therefore, one skilled in the art might suppose that printing by the first layer requires an extra amount of energy compared with printing by the second layer. But the actual increase in energy at the exothermic portion 104 is less than 10% of the heat generated at the exothermic portion 109, as shown in FIG. 15. In the case of simultaneous two line printing by the first layer and the second layer, the increase in energy supplied to the first layer is less than 10% of the heat generated at the exothermic portion 109.
Embodiment 5--Thermal Head
FIG. 12 and
Otherwise, the constitution of the fifth embodiment is the same as that of the third embodiment. For example, the exothermic portion 109 is shifted in the sub scan direction as shown in
The following describes the control method of the thermal head of the fifth embodiment. Control IC (not shown in
According to above mentioned third, fourth, and fifth embodiments, generally used ceramic substrates are suitable for the double-line thermal heads and the preheat thermal head, and these provide stable print quality. There is no need to use a stainless substrate or a metal common electrode in the thermal head, and no problem occurs due to differences of thermal expansion coefficients between a metal and glass glaze or alumina substrate. This thermal head is easily manufactured at low cost, because it is made in a way by similar to the conventional process.
Another merit of these embodiments is high density printing between the two lines without openings, because there is no common electrode between the two lines of the resistance exothermic portion. It should be noted that conventional double-line thermal heads have a common electrode between the two lines of the resistance exothermic portion. The third merit of these embodiments is that there is no heat loss between the resistance exothermic portion of first line and that of the second line, because there is no common electrode between the two lines of the resistance exothermic portion. It should be noted that conventional preheat thermal heads have a common electrode between the two line of the resistance exothermic portion. The fourth merit of these embodiments is that the layout can be freely made without restrictions between the exothermic portion of the first layer of an electric circuit pattern and the exothermic portion of the second layer of the electric circuit pattern. The reason for this is that the heat generated at the first layer of an electric circuit pattern is transmitted to the surface of the thermal head through the insulator layer formed on the first layer of an electric circuit pattern and the second layer of the electric circuit pattern.
Embodiment 6--Lamp
There are rear reflex boards 41a, 41b, rear-side reflex boards 42a, 42b, and side reflex boards 43a, 43b which are formed by parts of arcs so as to be concave mirrors to reflect incident light. The direction and position of each reflex board is set so that no shadows occur in incident light from the lamp 30. Furthermore, it is preferable that these reflex boards are aluminum boards with high reflectivity, thin boards having a flat surface with a coating of titanium nitride or metal film. The width of the rear-side reflex board 42a is expressed by the following equation established according to the diameter D of the lamp 30, and which is 28% narrower than the conventional structure:
The height H from irradiation surface 33 to the rear reflex board 41a is expressed by the following equation:
The following describes the working of the lamp reflex board of the sixth embodiment. The rear reflex boards 41a, 41b and the rear-side reflex boards 42a, 42b reflect radiant light 31a, 31b from the rear of lamp 30, and radiant light 31a, 31b reaches the irradiation surface 33. The side reflex boards 43a, 43b reflex radiant light 32a, 32b from the side of lamp 30 and radiant light 32a, 32b reaches the irradiation surface 33. In this way, radiant light from lamp 30 reaches the irradiation surface 33 efficiently. It is noted that the rear radiant light 31a, 31b is located between 135 degrees and 180 degrees of radiant angle ψ from the lamp 30, and the side radiant light 32a, 32b is located between 75 degrees and 135 degrees of radiant angle ψ from the lamp 30. Radiant angle ψ from the lamp 30 is defined so that the vertical direction of the irradiation surface 33 set to 0 degrees.
The following describes is the lamp cooling mechanism of the lamp reflex board of the sixth embodiment. The most efficient radiation of light by the lamp is at a temperature range of about 40 degrees centigrade. A conventional lamp requires air cooling by a fan, because the reflex board and the thermal paper enclose the lamp 30, and the temperature of the lamp 30 will become high without cooling. It is necessary to ventilate the lamp 30 through small gaps between the reflex board and the thermal paper. This leads to low cooling efficiency, and generates a temperature difference between the areas well ventilated with cooling ail and areas poorly ventilated with cooling air such as the rear of lamp 30.
The merit of the sixth embodiment is that the rear of the reflex board is well ventilated with cooling air, because the lamp reflex board is divided into three portions, such as the rear reflex boards 41a, 41b, rear-side reflex boards 42a, 42b, and side reflex boards 43a, 43b. This provides high cooling efficiency of the lamp, and inhibits local temperature differences. Even by air cooling without a blower, there is natural convection between the reflex boards, which provides high cooling efficiency of the lamp with an even temperature.
Although in the sixth embodiment, the lamp reflex board is divided into six portions on either the right or left side, such as rear reflex boards 41a, 41b, rear-side reflex boards 42a, 42b, and side reflex boards 43a, 43b. Those skilled in the art know that the number of divided portions of the lamp reflex board is not limited the above-mentioned six, but ten or more divided portions would also be acceptable. The shape of the lamp reflex board is not limited to arcs and flat boards, but polyhedrons, and minor ellipsoid concave would also be acceptable.
Another the merit of the sixth embodiment is that the width of the lamp reflex board is smaller than the conventional reflection surface of a concave mirror, because the divided reflex boards can be laid out separately. The separate reflex boards comprise rear reflex boards, rear-side reflex boards, and side reflex boards. The rear reflex boards are located at the back of the lamp, and it reflects radiant light from the back of the lamp to the side of the lamp. The rear-side reflex boards are located at the back and the side of lamp, and it reflect catoptric light from the rear reflex board to the irradiation surface. The side reflex boards are located at the side of lamp, and it reflect radiant light from the side of the lamp to the irradiation surface.
Matsuda, Hiroshi, Masukawa, Kazunori, Sugiyama, Hayami, Kawahara, Kenichi, Kawamura, Sigeyuki, Yamakuni, Minoru, Kubota, Takasi
Patent | Priority | Assignee | Title |
10279605, | Jun 29 2007 | APOLLO ADMINISTRATIVE AGENCY LLC | Printing system |
10370214, | May 31 2017 | Cryovac, LLC | Position control system and method |
6641314, | Mar 09 2001 | FUJIFILM Corporation | Color thermal printer having tension roller |
6681695, | Sep 17 2001 | Minami Co., Ltd. | Continuous printing and mounting apparatus for film-like printing body |
7119821, | Mar 26 2003 | FUJIFILM Corporation | Color thermal printer and color thermal printing method |
7289134, | May 27 2004 | ALPS Electric Co., Ltd. | Thermal printer including a plurality of recording units |
7967407, | Feb 03 2006 | APOLLO ADMINISTRATIVE AGENCY LLC | Use of a sense mark to control a printing system |
7973815, | Sep 30 2009 | Eastman Kodak Company | Method for controlling peel position in a printer |
7982758, | Sep 30 2009 | Eastman Kodak Company | Apparatus for controlling peel position in a printer |
8668328, | Nov 09 2007 | Hewlett-Packard Development Company, L.P. | Printer including positionable printing units |
8753026, | Jun 29 2007 | APOLLO ADMINISTRATIVE AGENCY LLC | Use of a sense mark to control a printing system |
9044977, | Jun 17 2011 | Xerox Corporation | System and method for threading a web through a printing device |
Patent | Priority | Assignee | Title |
3825722, | |||
4499529, | May 21 1981 | INTERLITE, INC | Light reflector |
5172136, | Sep 06 1991 | Eastman Kodak Company | Color registration is scanning thermal printer |
5386772, | Jun 15 1993 | IMPERIAL BANK | High speed media management device |
5549401, | Nov 13 1993 | Asahi Kogaku Kogyo Kabushiki Kaisha | Continuous form printer |
5847742, | Nov 16 1995 | FUJIFILM Corporation | Color thermal printer and color thermal printer method |
5937756, | Nov 10 1997 | Miyakoshi Printing Machinery Co., Ltd. | Tension control system for web in form printing press |
DE1115656, | |||
DE2459643, | |||
EP140690, | |||
EP562285, | |||
EP673776, | |||
JP10138541, | |||
JP10138547, | |||
JP10315518, | |||
JP3047771, | |||
JP61031268, | |||
JP61181659, | |||
JP62117763, | |||
JP6458566, | |||
JP8194343, | |||
JP9216390, | |||
JP9216391, |
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